MultiTech
Cellular library for MTS Socket Modem Arduino Shield devices from Multi-Tech Systems
Dependents: mtsas mtsas mtsas mtsas
Cellular/UIP.cpp
- Committer:
- Mike Fiore
- Date:
- 2014-05-21
- Revision:
- 10:c188cc05aed5
- Parent:
- 9:1a03e3f3e7fe
- Child:
- 11:4e428f689069
File content as of revision 10:c188cc05aed5:
#include "mbed.h"
#include "UIP.h"
#include "MTSText.h"
#include "MTSLog.h"
#include "CellUtils.h"
using namespace mts;
UIP::UIP()
{
io = NULL;
dcd = NULL;
dtr = NULL;
resetLine = NULL;
echoMode = true;
pppConnected = false;
mode = TCP;
socketOpened = false;
socketCloseable = true;
local_port = 0;
local_address = "";
host_port = 0;
}
UIP::~UIP()
{
if (dtr != NULL) {
dtr->write(1);
}
delete dcd;
delete dtr;
delete resetLine;
}
bool UIP::init(MTSBufferedIO* io)
{
if (! Cellular::init(io)) {
return false;
}
// Reset radio to make sure it's in a good state and wait for it to come back
reset();
test();
return true;
}
bool UIP::connect()
{
//Check if socket is open
if(socketOpened) {
return true;
}
//Check if already connected
if(isConnected()) {
return true;
}
Timer tmr;
//Check Registration: AT+CREG? == 0,1
tmr.start();
do {
Registration registration = getRegistration();
if(registration != REGISTERED) {
logWarning("Not Registered [%d] ... waiting", (int)registration);
wait(1);
} else {
break;
}
} while(tmr.read() < 30);
//Check RSSI: AT+CSQ
tmr.reset();
do {
int rssi = getSignalStrength();
logDebug("Signal strength: %d", rssi);
if(rssi == 99) {
logWarning("No Signal ... waiting");
wait(1);
} else {
break;
}
} while(tmr.read() < 30);
//AT#CONNECTIONSTART: Make a PPP connection
logDebug("Making PPP Connection Attempt. APN[%s]", apn.c_str());
std::string pppResult = sendCommand("AT#CONNECTIONSTART", 120000);
std::vector<std::string> parts = Text::split(pppResult, "\r\n");
if(pppResult.find("Ok_Info_GprsActivation") != std::string::npos) {
if(parts.size() >= 2) {
local_address = parts[1];
}
logInfo("PPP Connection Established: IP[%s]", local_address.c_str());
pppConnected = true;
} else {
pppConnected = false;
}
return pppConnected;
}
void UIP::disconnect()
{
//AT#CONNECTIONSTOP: Close a PPP connection
logDebug("Closing PPP Connection");
if(socketOpened) {
close();
}
Code code = sendBasicCommand("AT#CONNECTIONSTOP", 10000);
if(code == SUCCESS) {
logDebug("Successfully closed PPP Connection");
} else {
logError("Closing PPP Connection [%d]. Continuing ...", (int)code);
}
pppConnected = false;
}
bool UIP::isConnected()
{
//1) Check if APN was set
if(apn.size() == 0) {
logDebug("APN is not set");
return false;
}
//1) Check that we do not have a live connection up
if(socketOpened) {
logDebug("Socket is opened");
return true;
}
//2) Query the radio
std::string result = sendCommand("AT#VSTATE", 3000);
if(result.find("CONNECTED") != std::string::npos) {
if(pppConnected == false) {
logWarning("Internal PPP state tracking differs from radio (DISCONNECTED:CONNECTED)");
}
pppConnected = true;
} else {
if(pppConnected == true) {
//Find out what state is
size_t pos = result.find("STATE:");
if(pos != std::string::npos) {
result = Text::getLine(result, pos + sizeof("STATE:"), pos);
logWarning("Internal PPP state tracking differs from radio (CONNECTED:%s)", result.c_str());
} else {
logError("Unable to parse radio state: [%s]", result.c_str());
}
}
pppConnected = false;
}
return pppConnected;
}
bool UIP::bind(unsigned int port)
{
if(socketOpened) {
logError("socket is open. Can not set local port");
return false;
}
if(port > 65535) {
logError("port out of range (0-65535)");
return false;
}
local_port = port;
return true;
}
bool UIP::open(const std::string& address, unsigned int port, Mode mode)
{
char buffer[256] = {0};
Code portCode, addressCode;
//1) Check that we do not have a live connection up
if(socketOpened) {
//Check that the address, port, and mode match
if(host_address != address || host_port != port || this->mode != mode) {
if(this->mode == TCP) {
logError("TCP socket already opened [%s:%d]", host_address.c_str(), host_port);
} else {
logError("UDP socket already opened [%s:%d]", host_address.c_str(), host_port);
}
return false;
}
logDebug("Socket already opened");
return true;
}
//2) Check Parameters
if(port > 65535) {
logError("port out of range (0-65535)");
return false;
}
//3) Check PPP connection
if(!isConnected()) {
logError("PPP not established. Attempting to connect");
if(!connect()) {
logError("PPP connection failed");
return false;
} else {
logDebug("PPP connection established");
}
}
//Set Local Port
if(local_port != 0) {
//Attempt to set local port
sprintf(buffer, "AT#OUTPORT=%d", local_port);
Code code = sendBasicCommand(buffer, 1000);
if(code != SUCCESS) {
logWarning("Unable to set local port (%d) [%d]", local_port, (int) code);
}
}
//Set TCP/UDP parameters
if(mode == TCP) {
if(socketCloseable) {
Code code = sendBasicCommand("AT#DLEMODE=1,1", 1000);
if(code != SUCCESS) {
logWarning("Unable to set socket closeable [%d]", (int) code);
}
}
sprintf(buffer, "AT#TCPPORT=1,%d", port);
portCode = sendBasicCommand(buffer, 1000);
addressCode = sendBasicCommand("AT#TCPSERV=1,\"" + address + "\"", 1000);
} else {
if(socketCloseable) {
Code code = sendBasicCommand("AT#UDPDLEMODE=1", 1000);
if(code != SUCCESS) {
logWarning("Unable to set socket closeable [%d]", (int) code);
}
}
sprintf(buffer, "AT#UDPPORT=%d", port);
portCode = sendBasicCommand(buffer, 1000);
addressCode = sendBasicCommand("AT#UDPSERV=\"" + address + "\"", 1000);
}
if(portCode == SUCCESS) {
host_port = port;
} else {
logError("Host port could not be set");
}
if(addressCode == SUCCESS) {
host_address = address;
} else {
logError("Host address could not be set");
}
// Try and Connect
std::string sMode;
std::string sOpenSocketCmd;
if(mode == TCP) {
sOpenSocketCmd = "AT#OTCP=1";
sMode = "TCP";
} else {
sOpenSocketCmd = "AT#OUDP";
sMode = "UDP";
}
string response = sendCommand(sOpenSocketCmd, 30000);
if (response.find("Ok_Info_WaitingForData") != string::npos) {
logInfo("Opened %s Socket [%s:%d]", sMode.c_str(), address.c_str(), port);
socketOpened = true;
} else {
logWarning("Unable to open %s Socket [%s:%d]", sMode.c_str(), address.c_str(), port);
socketOpened = false;
}
return socketOpened;
}
bool UIP::isOpen()
{
if(io->readable()) {
logDebug("Assuming open, data available to read.\n\r");
return true;
}
return socketOpened;
}
bool UIP::close()
{
if(io == NULL) {
logError("MTSBufferedIO not set");
return false;
}
if(!socketOpened) {
logWarning("Socket close() called, but socket was not open");
return true;
}
if(!socketCloseable) {
logError("Socket is not closeable");
return false;
}
if(io->write(ETX, 1000) != 1) {
logError("Timed out attempting to close socket");
return false;
}
Timer tmr;
int counter = 0;
char tmp[256];
tmr.start();
do {
if(socketOpened == false) {
break;
}
read(tmp, 256, 1000);
} while(counter++ < 10);
io->rxClear();
io->txClear();
socketOpened = false;
return true;
}
int UIP::read(char* data, int max, int timeout)
{
if(io == NULL) {
logError("MTSBufferedIO not set");
return -1;
}
//Check that nothing is in the rx buffer
if(!socketOpened && !io->readable()) {
logError("Socket is not open");
return -1;
}
int bytesRead = 0;
if(timeout >= 0) {
bytesRead = io->read(data, max, static_cast<unsigned int>(timeout));
} else {
bytesRead = io->read(data, max);
}
if(bytesRead > 0 && socketCloseable) {
//Remove escape characters
int index = 0;
bool escapeFlag = false;
for(int i = 0; i < bytesRead; i++) {
if(data[i] == DLE || data[i] == ETX) {
if(escapeFlag == true) {
//This character has been escaped
escapeFlag = false;
} else if(data[bytesRead] == DLE) {
//Found escape character
escapeFlag = true;
continue;
} else {
//ETX sent without escape -> Socket closed
logInfo("Read ETX character without DLE escape. Socket closed");
socketOpened = false;
continue;
}
}
if(index != i) {
data[index] = data[i];
}
index++;
}
bytesRead = index;
}
//Scan for socket closed message
for(size_t i = 0; i < bytesRead; i++) {
if(data[i] == 'O') {
if(strstr(&data[i], "Ok_Info_SocketClosed")) {
logInfo("Found socket closed message. Socket closed");
//Close socket and Cut Off End of Message
socketOpened = false;
data[i] = '\0';
bytesRead = i;
break;
}
}
}
return bytesRead;
}
int UIP::write(const char* data, int length, int timeout)
{
if(io == NULL) {
logError("MTSBufferedIO not set");
return -1;
}
if(!socketOpened) {
logError("Socket is not open");
return -1;
}
//In order to avoid allocating another buffer, capture indices of
//characters to escape during write
int specialWritten = 0;
std::vector<int> vSpecial;
if(socketCloseable) {
for(int i = 0; i < length; i++) {
if(data[i] == ETX || data[i] == DLE) {
//Push back index of special characters
vSpecial.push_back(i);
}
}
}
int bytesWritten = 0;
if(timeout >= 0) {
Timer tmr;
tmr.start();
do {
int available = io->writeable();
if (available > 0) {
if(specialWritten < vSpecial.size()) {
//Check if current index is at a special character
if(bytesWritten == vSpecial[specialWritten]) {
if(available < 2) {
//Requires at least two bytes of space
wait(0.05);
continue;
}
//Ready to write special character
if(io->write(DLE)) {
specialWritten++;
if(io->write(data[bytesWritten])) {
bytesWritten++;
}
} else {
//Unable to write escape character, try again next round
wait(0.05);
}
} else {
//We want to write all the way up to the next special character
int relativeIndex = vSpecial[specialWritten] - bytesWritten;
int size = MIN(available, relativeIndex);
bytesWritten += io->write(&data[bytesWritten], size);
}
} else {
int size = MIN(available, length - bytesWritten);
bytesWritten += io->write(&data[bytesWritten], size);
}
} else {
wait(0.05);
}
} while (tmr.read_ms() <= timeout && bytesWritten < length);
} else {
for(int i = 0; i < vSpecial.size(); i++) {
//Write up to the special character, then write the special character
int size = vSpecial[i] - bytesWritten;
int currentWritten = io->write(&data[bytesWritten], size);
bytesWritten += currentWritten;
if(currentWritten != size) {
//Failed to write up to the special character.
return bytesWritten;
}
if(io->write(DLE) && io->write(data[bytesWritten])) {
bytesWritten++;
} else {
//Failed to write the special character.
return bytesWritten;
}
}
bytesWritten = io->write(&data[bytesWritten], length - bytesWritten);
}
return bytesWritten;
}
unsigned int UIP::readable()
{
if(io == NULL) {
logWarning("MTSBufferedIO not set");
return 0;
}
if(!socketOpened && !io->readable()) {
logWarning("Socket is not open");
return 0;
}
return io->readable();
}
unsigned int UIP::writeable()
{
if(io == NULL) {
logWarning("MTSBufferedIO not set");
return 0;
}
if(!socketOpened) {
logWarning("Socket is not open");
return 0;
}
return io->writeable();
}
bool UIP::setDeviceIP(std::string address)
{
if (address.compare("DHCP") == 0) {
return true;
} else {
logWarning("Radio does not support static IPs, using DHCP.\n\r");
return false;
}
}
void UIP::reset()
{
disconnect();
Code code = sendBasicCommand("AT#RESET=0", 10000);
if(code != SUCCESS) {
logError("Socket Modem did not accept RESET command\n\r");
} else {
logWarning("Socket Modem is resetting, allow 30 seconds for it to come back\n\r");
}
}
std::string UIP::getDeviceIP()
{
return local_address;
}
Code UIP::echo(bool state)
{
Code code;
if (state) {
code = sendBasicCommand("ATE0", 1000);
echoMode = (code == SUCCESS) ? false : echoMode;
} else {
code = sendBasicCommand("ATE1", 1000);
echoMode = (code == SUCCESS) ? true : echoMode;
}
return code;
}
bool UIP::ping(const std::string& address)
{
char buffer[256] = {0};
Code code;
code = sendBasicCommand("AT#PINGREMOTE=\"" + address + "\"", 1000);
if (code != SUCCESS) {
return false;
}
sprintf(buffer, "AT#PINGNUM=%d", 1);
code = sendBasicCommand(buffer , 1000);
if (code != SUCCESS) {
return false;
}
sprintf(buffer, "AT#PINGDELAY=%d", PINGDELAY);
code = sendBasicCommand(buffer , 1000);
if (code != SUCCESS) {
return false;
}
std::string response;
for (int i = 0; i < PINGNUM; i++) {
response = sendCommand("AT#PING", PINGDELAY * 1000);
if (response.find("alive") != std::string::npos) {
return true;
}
}
return false;
}
Code UIP::setSocketCloseable(bool enabled)
{
if(socketCloseable == enabled) {
return SUCCESS;
}
if(socketOpened) {
logError("socket is already opened. Can not set closeable");
return ERROR;
}
socketCloseable = enabled;
return SUCCESS;
}